AA Battery Solar Charger

AA Battery Solar Charger

(C) G. Forrest Cook 1999

Introduction

This almost trivial circuit may be used to charge a pair of AA or AAA
sized rechargeable battery cells from sunlight.
The circuit has been used to keep a variety of small electronic
devices running perpetually.
This is an unregulated charger, proper charging is achieved by placing
the unit in the sun for a known amount of time, this time varies according
to the battery type.

Specifications

Open Circuit Voltage: about 4.0V
Closed Circuit Current: about 25ma (depending on the solar cell types)
Charge Current: < 25ma (depending on the solar cell types)
Charge Time AA cells: approximately 1 full day of direct sunlight
Charge Time AAA cells: approximately 1/2 full day of sunlight

Theory

Each of the solar cells develops about 0.5 volts when in full sunlight.
The string of 8 solar cells puts out around 4V with no load.
When the solar cells are connected to a battery, the solar voltage will drop
to the battery voltage (around 2.4V) and charging current will flow through
the battery cells.

Two versions of the circuit are shown in the schematic,
the 8 solar cell panel with a diode is the recommended circuit.
The diode prevents the battery from discharging through
the cells at night and the 8th cell boosts the voltage up enough to compensate
for the voltage drop across the diode.
For an 8 solar cell panel, connect jumper J2 and disconnect J1.
For a 7 solar cell panel, connect jumper J1 and eliminate SC8 and D1.
Typically, the jumpers are not necessary, they are shown
in the schematic to illustrate two ways to to build the circuit.

For operation in cloudy weather, it may be useful to add one or two additional
solar cells. It is a good idea to temporarily insert a current meter
in series with the battery to measure the charging current in various
light conditions.

Since solar cells are current-limited devices, it is possible to
use the circuit as-is to charge a single battery cell.
If one cell is all you ever need to charge, five solar cells and a
series diode will be sufficient for the task.

Construction

Lay out the solar cells to determine the size of the circuit board, allow for
about 1/4" (1cm) of extra space around all four sides. Cut out one piece
of perforated circuit board, one piece of solid PC board, and one piece of
1/8" clear plexiglass in this dimension.
File all 3 pieces to achieve smooth edges.

Drill 2 holes down the center line of the 3 pieces while holding them together
allowing room for the screws to pass between the solar cells.
Mount the two battery holders on the blank piece of circuit board with screws
or silicon rubber glue.
If the solar cells don't have wire connections, solder thin wires to the cells.
Wire-wrap wire works well for this. Be careful not to overheat the solar cells,
use a small soldering iron and only touch the cells for a few seconds at a
time. The solar cells should be secured to the perf board
with a drop of silicon rubber on the back side, or they can be
held in place with the wires of the solar cell if you have the right
kind of cell.
Wire all of the cells in series, plus to minus, connect the two end
wires to longer wires that go to the diode and battery holder.
Typically, the positive connection is the metal on the back of the solar cell
and the negative connection is the wire grid on the blue (front) side.

Using a pair of 3/4 inch 6-32 machine screws and nuts or washers, make
a sandwich of the 3 boards. Use the nuts or washers to make gaps between
the board layers, it is important to prevent any contact between the
solar cells and the plexiglass. The solar cells are very brittle and will
break under compression.

If you want to make the panel waterproof,
cut 4 thin strips of solid circuit board or other plastic to
fit around the sides of the sandwich. Glue these boards to the sides
of the assembly with silicon rubber. Apply a small drop of glue to where
the screws go through the plexiglass.

Use

Insert two rechargeable cells into the battery holders, point the panel
towards the sun, and let batteries charge for a few hours.
For the fastest charging, keep the panel aimed at the sun throughout
the charging cycle.
Larger battery cells will need more charging time than smaller cells.
The solar array should be placed in direct sun, it should not be shaded
in any way.
It might be a good idea to monitor the battery voltage during the first
few charge cycles to get an idea of how much time is needed to reach
a full charge.

Do not let the rechargeable cells overheat. If the charger is left outdoors
in the summer, the excess heat can cause the cells to leak out their
electrolyte goo, ruining the cells. Operating the charger
indoors behind a window may help to reduce the heat.
Operation behind a window will also cause a drop in the charge current,
resulting in a longer charge time.

This circuit works with rechargeable alkaline cells, NICD cells, NiMH
cells or any other rechargeable that has a potential of 1.2-1.5V per cell.
If you build the 7 cell version with no diode, remove the cells at night to
prevent discharge through the solar cells.

It is advisable to connect a volt meter across the battery with a pair
of alligator clips to observe the battery voltage as it charges.
If you have a lot of batteries to charge, it is best to charge cells that
are matched by brand. If possible, use cell pairs that start with a similar
voltage, this allows both cells to finish charging at the same time.

The NiCd Memory Effect

Keep in mind that the so-called NiCd "memory effect" is largely an urban
legend that started from a legitimate early 1960s NASA experiment involving
first generation NiCd cells that were charged and discharged within a very
tight voltage range.
The two biggest killers of modern NiCd cells are overheating during
charging, and the reverse voltages applied to the weaker cells when
multi-cell NiCd packs are completely discharged.

Overheating of NiCD cells can cause the loss of electrolyte, resulting in
lowered cell capacity.
The NiCd cells in cheaper appliances such as cordless phones and portable
vacuum cleaners will last much longer if they are removed from the charger
as soon as they become warm. Leaving a NiCD pack in a charger 24 hours
a day will result in short battery life.

Reverse voltage can cause conductive
dendrites to grow in the cells making them self-discharge more rapidly.
So called "memory effect" battery dischargers can actually cause the reverse
voltage problem if used on multiple cell packs. The weakest cell in a pack
will go to zero volts, then negative volts as the stronger cells continue to
discharge.
Discharging can be a good way to insure that all cells are charged from the
same starting point, just be sure to limit the minimum discharge voltage to
around 1V per cell.